A dual role of erbB2 in myelination and in expansion of the schwann cell precursor pool.

Neuregulin-1 provides an important axonally derived signal for the survival and growth of developing Schwann cells, which is transmitted by the ErbB2/ErbB3 receptor tyrosine kinases. Null mutations of the neuregulin-1, erbB2, or erbB3 mouse genes cause severe deficits in early Schwann cell development. Here, we employ Cre-loxP technology to introduce erbB2 mutations late in Schwann cell development, using a Krox20-cre allele. Cre-mediated erbB2 ablation occurs perinatally in peripheral nerves, but already at E11 within spinal roots. The mutant mice exhibit a widespread peripheral neuropathy characterized by abnormally thin myelin sheaths, containing fewer myelin wraps. In addition, in spinal roots the Schwann cell precursor pool is not correctly established. Thus, the Neuregulin signaling system functions during multiple stages of Schwann cell development and is essential for correct myelination. The thickness of the myelin sheath is determined by the axon diameter, and we suggest that trophic signals provided by the nerve determine the number of times a Schwann cell wraps an axon.

A role of the cryptic gene in the correct establishment of the left-right axis.

During vertebrate embryogenesis, a left-right axis is established. The heart, associated vessels and inner organs adopt asymmetric spatial arrangements and morphologies. Secreted growth factors of the TGF-beta family, including nodal, lefty-1 and lefty-2, play crucial roles in establishing left-right asymmetries [1] [2] [3]. In zebrafish, nodal signalling requires the presence of one-eyed pinhead (oep), a member of the EGF-CFC family of membrane-associated proteins [4]. We have generated a mutant allele of cryptic, a mouse EGF-CFC gene [5]. Homozygous cryptic mutants developed to birth, but the majority died during the first week of life because of complex cardiac malformations such as malpositioning of the great arteries, and atrial-ventricular septal defects. Moreover, laterality defects, including right isomerism of the lungs, right or left positioning of the stomach and splenic hypoplasia were observed. Nodal gene expression in the node was initiated in cryptic mutant mice, but neither nodal, lefty-2 nor Pitx2 were expressed in the left lateral plate mesoderm. The laterality defects observed in cryptic(-/-) mice resemble those of mice lacking the type IIB activin receptor or the homeobox-containing factor Pitx2 [6] [7] [8] [9], and are reminiscent of the human asplenic syndrome [10]. Our results provide genetic evidence for a role of cryptic in the signalling cascade that determines left-right asymmetry.

Identification of a novel anti-integrin monoclonal antibody that recognises a ligand-induced binding site epitope on the beta 1 subunit.

Integrins are the major family of receptors involved in the adhesive interactions of cells with extracellular matrix macromolecules. Although it is known that integrins can exist in active or inactive states, the molecular mechanisms by which integrin activity is modulated are poorly understood. A novel anti-integrin monoclonal antibody, 12G10, that enhances alpha 5 beta 1-fibronectin interactions has been identified. 12G10 binds to the beta 1 subunit and appears to recognise a region of the subunit that contains the epitopes of several previously described activating or inhibitory monoclonal antibodies. However, unlike other activating anti-beta 1 antibodies, the binding of 12G10 to alpha 5 beta 1 is increased in the presence of ligands (fibronectin fragment or RGD peptide). This is the first report for the beta 1 integrin family of an antibody that recognises a ligand-induced binding site, and further emphasises the functional importance of a specific region of the beta 1 subunit in regulating integrin-ligand interactions.

BACE1 Dependent Neuregulin Proteolysis.

Neuregulin-1 (NRG1), which is also called acetylcholine receptor inducing activity (ARIA) or glial growth factor (GGF), signals as a ligand of ErbB receptors in a variety of important developmental processes but also later in life. NRG1 mediated signaling is crucial for cardiogenesis and the development of the breast. In the nervous system, NRG1 functions are essential for peripheral myelination, the establishment and maintenance of neuromuscular and sensorimotoric systems as well as for the plasticity of cortical neuronal circuits. There is strong evidence that deregulation of NRG1 is involved in breast cancer and schizophrenia. Many splice variants of NRG1 are expressed in the brain and all contain an EGF-like domain, which exerts the NRG1 function by limited proteolysis from its membrane bound precursor protein. In addition, most NRG1 isoforms contain a transmembrane domain, which is processed by γ-secretase after shedding. ß-Secretase (ß-site amyloid precursor protein cleaving enzyme 1; BACE1) has been identified based on its role as the rate limiting enzyme of amyloid-ß-peptide (Aß) production. Aß is the major component of amyloid plaques in Alzheimer`s disease (AD). More recently it was shown that Neuregulin-1 activity is highly dependent on the cleavage by BACE1 during early postnatal development. In BACE1 KO mice a role for BACE1 dependent proteolysis of NRG1 in the process of peripheral myelination could be demonstrated. Here we summarize the current knowledge about the role of NRG1 proteolysis for ErbB receptor mediated signaling during development and in Alzheimer`s disease.

Recent insights into ligand binding, activation and signalling by integrin adhesion receptors.

In recent years, analyses of the structure and function of membrane-intercalated adhesion molecules have shown them to play key roles in determining cellular phenotype. As expected, adhesion has an important role in regulating cellular positioning, but there is also compelling evidence that information transduced via adhesion molecules affects the differentiation status of cells. Cell surface adhesion molecules can be classified into a number of gene families, including immunoglobulins, cadherins, selectins, proteoglycans, and integrins. All of these types of molecule are co-expressed on most cells, and therefore the overall contribution of adhesion to cell phenotype is likely to be a net effect of the individual contributions of each of these groups. In this review, we will focus on the role of the integrins, which appear to be particularly important mediators of cell migration and adhesion-dependent intracellular signalling. A great deal is now known about the extracellular faces of integrins, including their structure and ligand-binding mechanisms, and in recent years, our knowledge of integrin-dependent signalling via cytoplasmic domains has improved considerably. An emerging picture is one of a dynamic family of receptors than can be expressed in different states of activation. Alterations in activity are apparently mediated by conformational changes that can be induced from both outside and inside cells. In turn, these changes in activity have concomitant consequences for adhesion and signalling.

Neuregulin, a factor with many functions in the life of a schwann cell.

The signalling system comprising the ligand Neuregulin-1, and its receptors, ErbB2 and ErbB3, plays multiple and important roles in glial development. These include functions in early development of neural crest cells, in expansion of the Schwann cell precursor pool and in myelination. Neuregulin is one of the crucial axon-derived signals that influence development of Schwann cells. These are specialized cells that ensheath peripheral axons and provide electrical insulation. Schwann cells have also long been implicated in providing more than a simple ensheathing function. Compelling evidence for this has emerged from the analysis of mice lacking these cells, resulting from a non-functional or compromised Neuregulin signalling system. They serve as a model to study glia-nerve interactions in vivo and indicate that Schwann cells provide important neurotrophic signals, and also cues that regulate perineurium development and nerve fasciculation.

Regulation of integrin function: evidence that bivalent-cation-induced conformational changes lead to the unmasking of ligand-binding sites within integrin alpha5 beta1.

The molecular mechanisms that regulate integrin-ligand binding are unknown; however, bivalent cations are essential for integrin activity. According to recent models of integrin tertiary structure, sites involved in ligand recognition are located on the upper face of the seven-bladed beta-propeller formed by the N-terminal repeats of the alpha subunit and on the von Willebrand factor A-domain-like region of the beta subunit. The epitopes of function-altering monoclonal antibodies (mAbs) cluster in these regions of the alpha and beta subunits; hence these mAbs can be used as probes to detect changes in the exposure or shape of the ligand-binding sites. Bivalent cations were found to alter the apparent affinity of binding of the inhibitory anti-alpha5 mAbs JBS5 and 16, the inhibitory anti-beta1 mAb 13, and the stimulatory anti-beta1 mAb 12G10 to alpha5 beta1. Analysis of the binding of these mAbs to alpha5beta1 over a range of Mn2+, Mg2+ or Ca2+ concentrations demonstrated that there was a concordance between the ability of cations to elicit conformational changes and the ligand-binding potential of alpha5 beta1. Competitive ELISA experiments provided evidence that the domains of the alpha5 and beta1 subunits recognized by mAbs JBS5/16 and 13/12G10 are spatially close, and that the distance between these two domains is increased when alpha5 beta1 is occupied by bivalent cations. Taken together, our findings suggest that bivalent cations induce a conformational relaxation in the integrin that results in exposure of ligand-binding sites, and that these sites lie near an interface between the alpha subunit beta-propeller and the beta subunit putative A-domain.

Integrin alpha 4 beta 1-mediated melanoma cell adhesion and migration on vascular cell adhesion molecule-1 (VCAM-1) and the alternatively spliced IIICS region of fibronectin.

The integrin receptor alpha 4 beta 1 (also known as VLA-4) binds two different ligands, the endothelial cell surface protein vascular cell adhesion molecule-1 (VCAM-1) and the extracellular matrix component fibronectin. Three distinct sites in fibronectin are recognized by alpha 4 beta 1. Two of these (represented by peptides CS1 and CS5) are present in the alternatively spliced IIICS region and lie in separate, independently spliced segments of this region. A third site resides in the adjacent constitutively expressed HepII domain. Recombinant proteins containing the HepII domain and different splice variants of the IIICS have been generated and compared for their ability to mediate cell attachment, spreading and migration. The activity of these proteins has also been compared with that of a recombinant soluble form of VCAM-1 (rsVCAM-1). All the recombinant proteins supported A375-SM human melanoma cell attachment and spreading in an alpha 4 beta 1-dependent manner, but had varied adhesive activities with rsVCAM-1 > fibronectin variants containing the CS1 sequence >> other fibronectin variants. Low concentrations of rsVCAM-1 and CS1-containing fibronectin variants effectively supported cell migration in a trans-filter assay; however, cell motility was retarded at high concentrations of the same proteins. Fibronectin variants lacking CS1 supported little or no migration. To obtain further insight into the molecular basis of this varied adhesive activity, apparent dissociation constants for each of the recombinant proteins were measured using a solid phase receptor-ligand binding assay. The results revealed a hierarchy of ligand affinities that mirrored their adhesive activity (rsVCAM-1 > fibronectin variants containing CS1 >> other fibronectin variants).